CN214725905U - High-precision in-mold insert injection molding positioning and feeding automatic system - Google Patents

Abstract

The utility model relates to the technical field of machining, specific mold insert injection moulding location and pay-off automation system in high accuracy mould that says so, the on-line screen storage device comprises a base, base upper end fixed mounting has electronic conveyer belt, electronic conveyer belt upper surface is connected with locating component, the inside both sides fixedly connected with fixed block of connecting block, the fixed block front end surface is rotated and is connected with L shape briquetting. The utility model discloses a to mould the body and place in the surface of shell, start the cylinder and promote the hydraulic stem that its is connected and remove in the shell, the promotion strip that makes its connection removes, remove with the draw-in groove sliding connection of push rod lower extreme promoting the strip, along with promoting the strip and remove and make push rod rebound, the U-shaped ejector pad of its middle part connection can promote L shape briquetting and rotate, its one end can compress tightly the body of moulding and fix a position, later start base upper end fixed connection's electric conveyor belt and carry out the locating component to its surface connection and carry.

Description

High-precision in-mold insert injection molding positioning and feeding automatic system

Technical Field

The utility model relates to a machinery processing technology field particularly, relates to a high accuracy mold insert injection moulding location in mould and pay-off automatic system.

Background

IMD is a technique of putting a printed and molded decorative sheet into an injection mold, then injecting gum on the back of the molded sheet, and bonding resin and the sheet into an integral body for curing molding. IMD is the technology of insert decoration while injection molding, the product is integrated with the decoration printing material, and the decoration printing can be carried out on the whole molded product, so that the product achieves the effect of integration of decoration and functionality. Embedded in the injection mould cavity and then matched with the mould for injection moulding to manufacture the product. It integrates the technologies of printing, forming, moulding and injection moulding into a whole, and can be used for the comprehensive application of plastic sheets, printing ink and plastic resin. The back of the film is combined with the ink layer by the injection molding resin, and the pictures, texts and marks of the panel are arranged between the film and the injection molding resin, so that the pictures, the texts and the marks cannot be abraded due to friction or time relation.

However, many existing devices do not have a good positioning function when used for insert molding, so that the insert is dislocated and the pattern is unclear, and meanwhile, when used for feeding, the manual feeding mode is adopted, so that the unsafe feeding speed is relatively slow.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a mold insert injection moulding location and pay-off automation system in high accuracy mould can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a high accuracy mold insert injection moulding location and pay-off automatic system, includes the base, base upper end fixed mounting has electronic conveyer belt, electronic conveyer belt upper surface is connected with locating component, locating component includes shell and connecting rod, electronic conveyer belt is connected to the shell lower extreme, shell one end is connected with the connecting rod, connecting rod one end is connected with the cylinder, cylinder one end is connected with the hydraulic stem, the hydraulic stem passes shell one end and promotes to be connected with and promote the strip, the shell upper end is connected with the connecting block, the inside both sides fixedly connected with fixed block of connecting block, the fixed block front end surface is rotated and is connected with L shape briquetting.

Preferably, a push rod penetrates through the inner part of the shell movably, and a clamping groove is formed in the lower end of the push rod.

Preferably, the clamping groove is internally and slidably connected with a pushing strip, one end of the pushing strip is connected with a sliding rod, and the sliding rod penetrates through the inner wall of the shell in a sliding mode.

Preferably, one end of the L-shaped pressing block is connected with a mould body in a compression mode, and the lower end of the mould body is connected with the shell.

Preferably, one end of the L-shaped pressing block is in contact connection with a U-shaped pushing block, and the U-shaped pushing block is fixed on the surface of the front end of the push rod.

Preferably, the two sides of the push rod are provided with sliders, the sliders are connected with the fixed block in a sliding mode, the upper end of the push rod is connected with a spring, the upper end of the spring is connected with a limiting block, and the upper end of the limiting block is connected with a connecting block.

Compared with the prior art, the utility model discloses following beneficial effect has:

(1) the mould body is placed on the surface of shell, the cylinder of connecting rod one end connection is started, promote the hydraulic stem of its connection and remove in the shell, when the hydraulic stem removes, the promotion strip that makes its connection removes, remove the draw-in groove sliding connection with the push rod lower extreme promoting the strip, remove along with promoting the strip and make the push rod rebound, when the push rod rebound, the U-shaped ejector pad of its middle part connection can promote its swing joint's L shape briquetting, make L shape briquetting rotate, its one end can compress tightly the mould body and fix a position when it rotates, when having realized inlaying the seal, good locate function has, more accuracy during the mold insert, the figure is more clear.

(2) After carrying out fixing a position the body of moulding, can start base upper end fixed connection's electronic conveyer belt and carry out the locating component who connects its surface and carry, accomplish the pay-off and carry out mold insert printing on next step, can start the cylinder after the printing is accomplished, go on to the hydraulic stem and promote the strip pulling, push rod downstream after that makes L shape briquetting break away from the location to the body of moulding, adopts the electronic conveyer belt mode to carry out the pay-off, and speed increases, more safety when its pay-off.

Drawings

FIG. 1 is a schematic view of a front view of an automatic system for positioning and feeding an insert for injection molding in a high precision mold of the present invention;

FIG. 2 is a schematic view of the internal partial structure of the high-precision in-mold insert injection molding positioning and feeding automatic system of the present invention;

FIG. 3 is an enlarged schematic view of the A position of the automatic system for positioning and feeding the high-precision in-mold insert injection molding of the present invention;

fig. 4 is the utility model relates to a B department of high accuracy in-mold insert injection moulding location and pay-off automatic system enlarges the schematic structure.

In the figure: 1. a base; 101. an electric conveyor belt; 2. a positioning assembly; 201. a housing; 202. a connecting rod; 203. a cylinder; 204. a hydraulic lever; 205. a push bar; 206. a slide bar; 207. a push rod; 208. a card slot; 209. connecting blocks; 210. a fixed block; 211. an L-shaped pressing block; 212. a U-shaped push block; 213. a slider; 214. a spring; 215. a limiting block; 3. a mould body.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

As shown in fig. 1-4, a high accuracy mold insert injection moulding location and pay-off automatic system, including base 1, base 1 upper end fixed mounting has electronic conveyer belt 101, electronic conveyer belt 101 upper surface is connected with locating component 2, locating component 2 includes shell 201 and connecting rod 202, electronic conveyer belt 101 is connected to shell 201 lower extreme, shell 201 one end is connected with connecting rod 202, connecting rod 202 one end is connected with cylinder 203, cylinder 203 one end is connected with hydraulic stem 204, hydraulic stem 204 passes shell 201 one end and promotes to be connected with and promote strip 205, shell 201 upper end is connected with connecting block 209, the inside both sides fixedly connected with fixed block 210 of connecting block 209, fixed block 210 front end surface rotates and is connected with L shape briquetting 211.

In this embodiment, the mold body 3 is placed above the housing 201, the cylinder 203 connected to one end of the connecting rod 202 is actuated to push the hydraulic rod 204 connected to the cylinder to move in the housing 201, when the hydraulic rod 204 moves, the pushing bar 205 connected to the hydraulic rod is moved, when the pushing bar 205 moves, the pushing bar 205 moves to be slidably connected to the slot 208 at the lower end of the pushing bar 207, when the pushing bar 205 moves, the pushing bar 207 moves upward, when the pushing bar 207 moves upward, the U-shaped pushing block 212 connected to the middle part thereof pushes the L-shaped pressing block 211 movably connected to the pushing bar, so that the L-shaped pressing block 211 rotates, and when the pushing bar rotates, one end thereof presses the mold body 3 to be positioned, as shown in fig. 2;

after the plastic mould body 3 is positioned, the electric conveying belt 101 fixedly connected with the upper end of the base 1 can be started to convey the positioning component 2 connected with the surface of the base, feeding is completed to perform insert printing on the next step, the air cylinder 203 can be started after printing is completed to pull the hydraulic rod 204 and the push bar 205, and then the push rod 207 moves downwards to enable the L-shaped pressing block to be separated from the plastic mould body 3.

In the application, a push rod 207 is movably connected to the inside of the housing 201 in a penetrating manner, a clamping groove 208 is formed in the lower end of the push rod 207, the push rod 205 moves and is slidably connected with the clamping groove 208 in the lower end of the push rod 207, and the push rod 207 moves upwards along with the movement of the push rod 205.

In this application, sliding connection pushes away strip 205 in draw-in groove 208, and it is connected with slide bar 206 to push away strip 205 one end, and slide bar 206 slides and passes shell 201 inner wall, when removing through pushing away strip 205, carries out sliding connection with draw-in groove 208, and slide bar 206 slides at shell 201 simultaneously, guarantees to push away the stability of strip 205.

In the present application, one end of the L-shaped pressing block 211 is connected to the mold body 3 in a pressing manner, the lower end of the mold body 3 is connected to the housing 201, and when the L-shaped pressing block 211 rotates, one end of the L-shaped pressing block compresses the mold body 3 for positioning.

In the present application, one end of the L-shaped pressing block 211 is connected to a U-shaped pushing block 212 in a contacting manner, the U-shaped pushing block 212 is fixed on the front end surface of the pushing rod 207, and the L-shaped pressing block 211 connected to the U-shaped pushing block 212 is pushed by the U-shaped pushing block 212 to rotate.

In this application, push rod 207 both sides are equipped with slider 213, slider 213 sliding connection fixed block 210, and push rod 207 upper end is connected with spring 214, and spring 214 upper end is connected with stopper 215, and connecting block 209 is connected to stopper 215 upper end, and when upwards or the downward movement through push rod 207, slider 213 that its both sides are connected slides in fixed block 210 one side, promotes spring 214 when push rod 207 moves to the upper end simultaneously, produces bounce, and then stabilizes push rod 207 and reciprocates.

The utility model provides a high accuracy mould inner inlay piece injection moulding location and pay-off automation system's theory of operation:

when the injection molding machine is used, firstly, the molding body 3 is placed on the surface of the shell 201, the air cylinder 203 connected with one end of the connecting rod 202 is started to push the hydraulic rod 204 connected with the connecting rod to move in the shell 201, when the hydraulic rod 204 moves, the pushing bar 205 connected with the hydraulic rod 204 moves, the pushing bar 205 moves to be in sliding connection with the clamping groove 208 at the lower end of the pushing rod 207, the pushing rod 207 moves upwards along with the movement of the pushing bar 205, when the pushing rod 207 moves upwards, the U-shaped pushing block 212 connected with the middle part of the hydraulic rod pushes the L-shaped pressing block 211 movably connected with the hydraulic rod to rotate the L-shaped pressing block 211, and when the L-shaped pressing block rotates, one end of the L-shaped pressing molding body 3 is pressed to be positioned, as shown in fig. 2;

after the plastic mould body 3 is positioned, the electric conveying belt 101 fixedly connected with the upper end of the base 1 can be started to convey the positioning component 2 connected with the surface of the base, feeding is completed to perform insert printing on the next step, the air cylinder 203 can be started after printing is completed to pull the hydraulic rod 204 and the push bar 205, and then the push rod 207 moves downwards to enable the L-shaped pressing block to be separated from the positioning of the plastic mould body 3.

The specific specifications of the electric conveyor belt 101 and the hydraulic rod 204 are SSJ001 and XDHF12, respectively.

The power supply of the motorized conveyor belt 101 and its principle will be clear to the skilled person and will not be described in detail here.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a high accuracy in-mold insert injection moulding location and pay-off automatic system, includes base (1), its characterized in that: base (1) upper end fixed mounting has electronic conveyer belt (101), surface connection has locating component (2) on electronic conveyer belt (101), locating component (2) are including shell (201) and connecting rod (202), electronic conveyer belt (101) are connected to shell (201) lower extreme, shell (201) one end is connected with connecting rod (202), connecting rod (202) one end is connected with cylinder (203), cylinder (203) one end is connected with hydraulic stem (204), hydraulic stem (204) pass shell (201) one end and promote to be connected with and promote strip (205), shell (201) upper end is connected with connecting block (209), inside both sides fixedly connected with fixed block (210) of connecting block (209), fixed block (210) front end surface rotates and is connected with L shape briquetting (211).

2. The high precision in-mold insert injection molding positioning and feeding automation system as claimed in claim 1, characterized in that: the inner part of the shell (201) is movably connected with a push rod (207) in a penetrating mode, and a clamping groove (208) is formed in the lower end of the push rod (207).

3. The high precision in-mold insert injection molding positioning and feeding automation system as claimed in claim 2, characterized in that: the push bar (205) is connected in the clamping groove (208) in a sliding mode, one end of the push bar (205) is connected with a slide bar (206), and the slide bar (206) penetrates through the inner wall of the shell (201) in a sliding mode.

4. The high precision in-mold insert injection molding positioning and feeding automation system as claimed in claim 1, characterized in that: one end of the L-shaped pressing block (211) is connected with a mould body (3) in a pressing mode, and the lower end of the mould body (3) is connected with the shell (201).

5. The high precision in-mold insert injection molding positioning and feeding automation system as claimed in claim 1, characterized in that: one end of the L-shaped pressing block (211) is in contact connection with a U-shaped pushing block (212), and the U-shaped pushing block (212) is fixed on the surface of the front end of the push rod (207).

6. The automatic positioning and feeding system for high-precision in-mold insert injection molding according to claim 5, wherein: the improved push rod structure is characterized in that sliding blocks (213) are arranged on two sides of the push rod (207), the sliding blocks (213) are connected with fixing blocks (210) in a sliding mode, springs (214) are connected to the upper end of the push rod (207), limiting blocks (215) are connected to the upper ends of the springs (214), and connecting blocks (209) are connected to the upper ends of the limiting blocks (215).

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